Ultra high frequency radio frequency identification tag

ABSTRACT

An antenna design for radio frequency identification (“RFID”) tags. More particularly, the present invention relates to design for RFID tags particularly operating in the ultra high frequency (“UHF”) operating band.

TECHNICAL FIELD

The present invention relates to antenna design for radio frequencyidentification (“RFID”) tags. More particularly, the present inventionrelates to design for RFID tags particularly operating in the ultra highfrequency (“UHF”) operating band.

BACKGROUND OF THE INVENTION

Radio frequency identification (“RFID”) has been proposed for use in anumber of applications in which an RFID tag is attached to an item andsubsequently interrogated or read to obtain information regarding thatitem. For example, U.S. Pat. Nos. 6,232,870 and 6,486,780, and PCTPublication WO 00/10122 describe various functions and applications forRFID systems, and exemplify the use of RFID tags in libraries. U.S. Pat.No. 5,963,134 also describes certain uses for RFID systems in librariesand for other applications.

The design of a typical RFID tag reflects its origin in thesemiconductor and printed circuit board industries. Although functional,the design has a number of features that increase the cost of thefinished article and efficiency especially at ultra high frequencies(“UHF”). In a resonant RFID tag, the electrical inductance of an antennais connected in parallel with a capacitor such that the resonantfrequency of the thus-formed circuit is tuned to a prescribed value. Inmore advanced forms, the circuit of the RFID tag may include anintegrated circuit electrically and mechanically bonded to the antennaon a substrate, wherein the voltage induced in/on the antenna by areader signal provides power to operate the integrated circuit.

Various methods have been developed to design RFID tags, such asdisclosed in the following references: U.S. Pat. No. 6,501,435; U.S.Pat. No. 6,100,804; and PCT Publication WO 00/26993.

SUMMARY OF THE INVENTION

One aspect of the present invention provides an ultra high frequency(“UHF”) radio frequency identification (“RFID”) tag. The UHF RFID tag,comprises: a) a dielectric substrate; b) an antenna attached to thedielectric substrate, where the antenna comprises: i) a first antennaelement, where the first antenna element comprises a first conductor anda second conductor, where each conductor has a first end and a secondend opposite the first end, where the first antenna element is selectedto provide a desired operating frequency range of the antenna; and ii) asecond antenna element, where the second antenna element comprises afirst portion and a second portion, where the first portion is attachedto the second end of the first conductor and the second portion isattached to the second end of the second conductor, and where the secondantenna element is selected to provide a desired impedance value of theantenna; and c) an integrated circuit attached to the first end of thefirst conductor and the first end of the second conductor.

In one preferred embodiment of the above UHF RFID tag, the integratedcircuit has a first impedance value, the second antenna element has asecond impedance value, the magnitude of the real component of thesecond impedance value is substantially similar to the magnitude of thereal component of the first impedance value, and the magnitude of theimaginary component of the second impedance value is substantiallysimilar to the magnitude of the imaginary component of the firstimpedance value, and the phase of the imaginary component of the firstimpedance value and phase of the imaginary component of the secondimpedance value are opposite. In another aspect of this embodiment, thefirst impedance value has a first real component value and a firstimaginary component value, the second impedance value has a second realcomponent value and a second imaginary component value, the first realcomponent value is substantially similar to the second real componentvalue and the first imaginary component value is substantially similarto the second imaginary component value, where the magnitude of theimaginary component of the second impedance value is substantiallysimilar to the magnitude of the imaginary component of the imaginarycomponent of the first impedance value, and the phase of the imaginarycomponent of the first impedance value and phase of the imaginarycomponent of the second impedance value are opposite. In another aspectof this embodiment, the first impedance value has a first real componentvalue and a first imaginary component value, the second impedance valuehas a second real component value and a second imaginary componentvalue, where the first real component value is equal to the second realcomponent value and the first imaginary component value is equal to thesecond imaginary component value, the magnitude of the imaginarycomponent of the second impedance value is equal to the magnitude of theimaginary component of the imaginary component of the first impedancevalue, and the phase of the imaginary component of the first impedancevalue and phase of the imaginary component of the second impedance valueare opposite.

In another preferred embodiment of the above UHF RFID tag, the firstportion of the antenna has a first real component value and a firstimaginary component value and the second portion of the antenna has asecond real component value and a second imaginary component value, andthe second portion of the antenna is selected to provide a second realcomponent value and second imaginary component value which assist inbalancing the first real component value and the first imaginarycomponent value to provide the second impedance value of the antennasubstantially similar to the first impedance value of the integratedcircuit. In another aspect of this embodiment, the first portion of theantenna has a first real component value and a first imaginary componentvalue and the second portion of the antenna has a second real componentvalue and a second imaginary component value, the second portion of theantenna is selected to provide a second real component value and secondimaginary component value which assist in balancing the first realcomponent value and the first imaginary component value to provide thesecond impedance value of the antenna equal to the first impedance valueof the integrated circuit.

In another preferred embodiment of the above UHF RFID tag, the firstportion of the second antenna element and the second portion of thesecond antenna element are in the shape of closed loops. In anotherpreferred embodiment of the above UHF RFID tag, the first portion of thesecond antenna element and the second portion of the second antennaelement are in the shape of polygons. In yet another preferredembodiment of the above UHF RFID tag, the first portion of the secondantenna element is dissimilar in shape to the second portion of thesecond antenna element.

In another preferred embodiment of the above UHF RFID tag, the firstportion of the second antenna element is similar in shape to the secondportion of the second antenna element. In yet another preferredembodiment of the above UHF RFID tag, the first portion of the secondantenna element is different in size than the second portion of thesecond antenna element. In another preferred embodiment of the above UHFRFID tag, the first conductor and second conductor include meanders. Inanother preferred embodiment of the above UHF RFID tag, the firstconductor and second conductor are made from a wire, patternedconductive foils, or printed conductive traces. In another preferredembodiment of the above UHF RFID tag, the first antenna element is madefrom a different conductive material than the second antenna element.

In yet another preferred embodiment of the above UHF RFID tag, thedielectric substrate includes a dielectric constant

between 850 MHz and 960 MHz, where □₀ is the permittivity of free space(□₀=8.85×10⁻¹² C²/N.m²). In another preferred embodiment of the aboveUHF RFID tag, the dielectric substrate includes a first side and asecond side opposite the first side, where the antenna is attached tothe first side and the integrated chip is attached to the second side.In another preferred embodiment of the above UHF RFID tag, the distancebetween the first portion of the second antenna element and the firstconductor is different from the distance between the second portion ofthe second antenna element and the second conductor. In anotherpreferred embodiment of the above UHF RFID tag, the length of the firstconductor is different than the length of the second conductor.

Another aspect of the present invention provides a method ofmanufacturing an ultra high frequency (“UHF”) radio frequencyidentification (“RFID”) tag. This method comprises the steps of: a)providing a dielectric substrate; b) selecting an antenna comprised of afirst antenna element and a second antenna element, where the firstantenna element is selected to provide a desired operating frequencyrange of the antenna, where the second antenna element is selected toprovide a desired impedance value, where the first antenna elementcomprises a first conductor and a second conductor, where each conductorhas a first end and a second end opposite the first end, and where thesecond antenna element comprises a first portion and a second portion;and c) attaching the antenna to the dielectric substrate such that thefirst portion of the second antenna element is attached to the secondend of the first conductor and the second portion of the second antennaelement is attached to the second end of the second conductor; and d)attaching an integrated circuit to the first end of the first conductorand the first end of the second conductor.

In one preferred embodiment of the above method, the integrated circuithas a first impedance value, and the second antenna element has a secondimpedance value, the magnitude of the real component of the secondimpedance value is substantially similar to the magnitude of the realcomponent of the first impedance value, the magnitude of the imaginarycomponent of the second impedance value is substantially similar to themagnitude of the imaginary component of the first impedance value, andthe phase of the imaginary component of the first impedance value andphase of the imaginary component of the second impedance value areopposite. In another aspect of this embodiment, the first impedancevalue has a first real component value and a first imaginary componentvalue, the second impedance value has a second real component value anda second imaginary component value, the first real component value issubstantially similar to the second real component value and the firstimaginary component value is substantially similar to the secondimaginary component value, the magnitude of the imaginary component ofthe second impedance value is substantially similar to the magnitude ofthe imaginary component of the imaginary component of the firstimpedance value, and the phase of the imaginary component of the firstimpedance value and phase of the imaginary component of the secondimpedance value are opposite. In another aspect of this embodiment, thefirst impedance value has a first real component value and a firstimaginary component value, where the second impedance value has a secondreal component value and a second imaginary component value, the firstreal component value is equal to the second real component value and thefirst imaginary component value is equal to the second imaginarycomponent value, the magnitude of the imaginary component of the secondimpedance value is equal to the magnitude of the imaginary component ofthe imaginary component of the first impedance value, and the phase ofthe imaginary component of the first impedance value and phase of theimaginary component of the second impedance value are opposite.

In another preferred embodiment of the above method, the first portionof the antenna has a first real component value and a first imaginarycomponent value and the second portion of the antenna has a second realcomponent value and a second imaginary component value, the secondportion of the antenna is selected to provide a second real componentvalue and second imaginary component value which assist in balancing thefirst real component value and the first imaginary component value toprovide the second impedance value of the antenna substantially similarto the first impedance value of the integrated circuit. In anotheraspect of this embodiment, the first portion of the antenna has a firstreal component value and a first imaginary component value and thesecond portion of the antenna has a second real component value and asecond imaginary component value, the second portion of the antenna isselected to provide a second real component value and second imaginarycomponent value which assist in balancing the first real component valueand the first imaginary component value to provide the second impedancevalue of the antenna equal to the first impedance value of theintegrated circuit.

In another preferred embodiment of the above method, the first portionof the second antenna element and the second portion of the secondantenna element are in the shape of closed loops. In another preferredembodiment of the above method, the first portion of the second antennaelement and the second portion of the second antenna element are in theshape of polygons. In yet another preferred embodiment of the abovemethod, the first portion of the second antenna element is dissimilar inshape to the second portion of the second antenna element. In anotherpreferred embodiment of the above method, the first portion of thesecond antenna element is similar in shape to the second portion of thesecond antenna element. In another preferred embodiment of the abovemethod, the first portion of the second antenna element is different insize than the second portion of the second antenna element.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be further explained with reference to theappended Figures, wherein like structure is referred to by like numeralsthroughout the several views, and wherein:

FIG. 1 is a top view of one embodiment of the RFID tag of the presentinvention;

FIG. 2 is a graph illustrating the calculated impedance of a prior artfolded dipole antenna; and

FIG. 3 is a graph illustrating the calculated impedance of the antennaof the RFID tag of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is useful for radio frequency identification(“RFID”) tags operating in the ultra high frequency (“UHF”) band, whichgenerally ranges from 850 MHz to 960 MHz; preferably 868 MHz for Europe,915 MHz for the USA, and 956 MHz for Japan.

RFID tags may be either active or passive. Passive RFID tags,particularly those operating in the UHF band, use radio frequencysignals from an incident electromagnetic field sent out by an RFIDreader to power the tag. The radio frequency reader may provide aninterface between a data management system and the RFID tag, or betweenthe user and the RFID tag. When the RFID tag receives the radiofrequency signal from the incident electromagnetic field, the antennaabsorbs the radio frequency energy received from the radio frequencysignal and directs the energy to the integrated circuit on the RFID tag.The integrated circuit converts some portion of the absorbed radiofrequency energy into electrical potential energy and stores this energyin a section of the internal circuitry of the integrated circuit. Theelectrical potential energy appears as a voltage at the internal powersupply connections in the integrated circuit. The other circuits in theintegrated circuit, including the microprocessor, optional memory, anddecoding and encoding circuits for communications are powered by thisstored energy.

The incident electromagnetic energy from the RFID Reader may containdata or instructions encoded into the radio frequency signal. Theinstructions may include commands to the RFID tag to communicate itsserial number or the contents of data registers in the integratedcircuit. Using the energy stored on the integrated circuit, theintegrated circuit can then communicate back to the RFID reader thedetails of data stored in the integrated circuit's on-board memory. Thedistance at which an RFID tag can be “read”, i.e., participate intwo-way communication with the RFID Reader, depends on the output powerof the RFID reader, the surrounding environment, and the efficiency withwhich the RFID tag interacts with the incident electromagnetic field.The range at which the RFID tag can “write” new data to its memory isgenerally less than the “read” range, because of the generally highervoltages required for a “write” operation. For UHF RFID tags inparticular, the RFID tag communicates with the RFID reader by modulatingthe load on the RFID antenna, causing a portion of the incidentelectromagnetic energy to be back-scattered to the RFID reader. Thereader receives the back-scattered electromagnetic radiation and decodesthe modulated signal.

With RFID reader power emission limited by government regulations,improved read range will most likely only be possible with moreefficient tag antenna designs. Therefore, increased efficiency of theantenna absorption of the incident radio frequency energy and transferof the absorbed energy to the integrated circuit is desired. A UHF RFIDtag antenna should be efficient to absorb the incident electromagneticradiation and to back-scatter electromagnetic radiation back to the RFIDreader. Furthermore, the connection between the RFID tag antenna and theintegrated circuit needs to be efficient to supply sufficient energy tothe integrated circuit, even at the upper limit of the operatingdistance, i.e., at large distances separating the RFID reader and RFIDtag, for example three meters.

The efficiency of the interaction of the electromagnetic field with theRFID tag depends on the RFID tag antenna design and the efficiency ofcoupling the electromagnetic energy from the antenna into the integratedcircuit. This efficiency is related to the impedance of the antenna andthe impedance of the integrated circuit. Moderately efficient UHFantennas can be made from dipoles or two conductors, preferably on theorder of one-half wavelength. At 900 MHz, the free space wavelength isapproximately 300 mm. Efficient coupling of electromagnetic energybetween the antenna and the integrated circuit depends on substantiallymatching or exactly matching the impedance of the antenna to theimpedance at the input connections of the integrated circuit. Theimpedance Z can be represented by a complex number, in which the realcomponent (represented as Re Z) represents resistive loads where atime-varying current in phase with the voltage (φ=0, where φ is definedas the phase angle between the voltage and current waveforms) leads to adissipative (resistive) loss function. The imaginary component(represented as Im Z) represents a time-varying voltage that leads(φ=π/2, inductive) or lags (φ=−π/2, capacitive) the time-varying currentin the restricted load by the characteristic phase angle φ. The compleximpedance of the antenna and the complex impedance of the integratedcircuit can be represented by a sum of a real component and of animaginary component. The complex representations of impedance, voltage,and current may be manipulated using the customary mathematical rulesfor complex variables.

Efficient coupling of electromagnetic energy across the inputconnections between the antenna and integrated circuit is achieved bydesigning the real component of the antenna impedance (Re Z_(ANT)) to beclose to, and preferably equal to, the real component of the integratedcircuit input impedance (Re Z_(IC)). Matching the real components of theantenna and integrated circuit input impedance will help minimizereflection of electromagnetic energy at the boundary between the antennaand integrated circuit connection points, making the RFID tag moreefficient. This phenomenon is taught in The Art of Electronics, by PaulHorowitz and Winfield Hill (Cambridge University Press, Cambridge,England) 1980, pp. 565-568, which is hereby incorporated by reference.

In various operating frequency bands including in particular UHFoperating bands, the imaginary impedance of the antenna and theimaginary impedance of the integrated circuit (Im Z_(ANT) and Im Z_(IC),respectively) will affect the efficiency of power transfer into theintegrated circuit. The term “power factor” is used to characterize theefficiency with which the absorbed radio frequency electromagneticenergy sent by the RFID reader absorbed by the antenna will be convertedinto stored energy in the integrated circuit. (The definition andexplanation of power factor is further discussed in The Art ofElectronics, by Paul Horowitz and Winfield Hill (Cambridge UniversityPress, Cambridge, England) 1980, pp. 29 which is hereby incorporated byreference.) The power factor is at a maximum when the current andvoltage are in phase, which can be achieved by balancing the imaginary(capacitive) impedance component of the integrated circuit input withthe imaginary (inductive) impedance component of the antenna.

The operation of a simple dipole antenna is well understood by thoseskilled in the art and may be described by Maxwell's equations. Simpledipole antennas are further discussed in Elements of Physics, by GeorgeShortley and Dudley Williams, Prentice-Hall, Inc., Englewood Cliffs,N.J. (1971), which is hereby incorporated by reference. The overallphysical length of a dipole antenna may be decreased using meanders 30,which are curved portions or a circuitous circuit path along the dipoleantenna to increase the effective electrical length (signal path) of thedipole antenna, while maintaining a preferred physical length. Themeanders may be uniform or non uniform.

Another variation of the dipole antenna, which is also well known in theart, is the folded dipole, where the two free distal ends extending ofopposite the integrated circuit are folded back on themselves and areelectrically connected. The impedance of an example folded dipoleantenna, where the length of the straight section of the folded dipoleantenna is 140 mm, is calculated to be:Z _(FOLDED DIPOLE)(1₀=140 mm)=(24.58 Ω, −j 13.93 Ω) at f=915 MHz,where 1₀ is the end-to-end length of the straight section in the foldeddipole antenna. The calculation was performed using NEC (NumericalElectromagnetics Code) Win-Pro, which is commercially available fromNittany Scientific located in Riverton, Utah. If the length of thisexample folded dipole is reduced effective in length by 1%, calculationsshow that the impedance shifts to:Z _(FOLDED DIPOLE)(1=0.99*1₀)=(4.83 Ω, −j 8.635 Ω) at f=915 MHz.This large shift in calculated antenna impedance for a relatively smallshift in the folded dipole physical characteristic length illustratesthe sensitivity of the folded dipole antenna to small variations in itsoverall length.

The RFID tag of the present invention provides antenna designs thatefficiently couples radio frequency power received by the antenna to theRFID integrated circuit, particularly those RFID tags operating in theUHF operating band. The antenna design is compact, making it suitablefor RFID labels or similar applications where it is desirable tominimize the overall RFID tag size. The antenna design may be easilymodified to assist in matching and balancing the complex antennaimpedance and the complex input impedance of the integrate circuit atthe selected operating frequency.

FIG. 1 illustrates one embodiment of the inventive RFID tag 10. The RFIDtag 10 is especially useful in the UHF ranges, and hence, may be an UHFRFID tag 10. The RFID tag 10 includes a dielectric substrate 12 having afirst side 14 and a second side 16 opposite the first side 16. Antenna18 is attached to the first side 14 of the dielectric substrate 12.Preferably, antenna 18 is attached to the dielectric substrate 12 by anymeans know in the art, for example, by lamination with a pressuresensitive, curable adhesive film or by direct deposition on thesubstrate. The RFID tag 10 also includes an integrated circuit 36attached to the first side 14 of the dielectric substrate 12.Preferably, the integrated circuit 36 is attached to the dielectricsubstrate 12 by any means know in the art, for example, by anisotropicconductive film adhesive, solder, or thermo-compression bonding.

The antenna 18 includes a first antenna element 20 and a second antennaelement 22. The first antenna 20 preferably is a dipole antennaincluding a first conductor 24 and a second conductor 26. In onepreferred embodiment, the conductors 24, 26 include meanders 30.Meanders 30 help decrease the overall physical length of the dipoleantenna and assist in increasing the electrical length (signal path).Each conductor 24, 26 includes a first end 27 and a second end 28opposite the first end 27. The second antenna element includes a firstportion 32 and a second portion 34. In one preferred embodiment, thefirst portion 32 and the second portion 34 are in the shape of closedloops or polygons. In one example, as illustrated in FIG. 1, the firstportion 32 may be in the shape of a circle and the second portion 34 maybe in the shape of an ellipse. However, the portions 32, 34 of thesecond antenna element may be any shape. The portions 32, 34 of thesecond antenna element may be shaped similarly, or the same. Theportions 32, 34 of the second antenna element may be sized to be similarin size, or different in size. However, the shape and size of theportions 32, 34 of the second antenna element may be selected by oneskilled in the art to assist in balancing the impedance of the antenna18 with the impedance of the integrated circuit 36, as discussed below.

The first end 27 of the conductors 24, 26 are electrically connected tothe integrated circuit 36, preferably by individual terminal pads (notshown). In one preferred embodiment, the second end 28 of the firstconductor 24 is attached or is electrically connected to the firstportion 32 of the second antenna element 22 and the second end 28 of thesecond conductor 26 is attached or electrically connected to the secondportion 34 of the second antenna element 22. The length “c” measuredbetween the second end 28 of the first conductor 24 and the curvedportion of the first conductor 24 (as illustrated in FIG. 1) may beequal to or different than the length “d” measured between the secondend 28 of the second conductor 26 and the curved portion 3 of the secondconductive 24. The lengths c and d respectfully, may be selected by oneskilled in the art to assist in balancing the impedance of the antenna18 with the impedance of the integrated circuit 36, as discussed below.

To tune the operating frequency band of the RFID antenna 18, the lengthof first conductor 24 and second conductor 26, which make up the firstantenna element 20, may be modified. By selecting the length of thefirst conductor 24 and the second conductor 26, the first antennaelement 20 may be selected to determine the operating frequency range ofthe antenna 18 of the RFID tag 10. The lengths of the conductors 24, 26may be the same or different. Preferred lengths of the conductors 24, 26are in the range of 85 mm. to 170 mm., and more preferred lengths of theconductors 24, 26 are approximately 140 mm.

The design of the first antenna element 20 also assists in matching thereal part of the impedance of the antenna 18 to the real part of theinput impedance of the integrated circuit 36. The design of the firstantenna elements 20 provide a means by which the real part of theimpedance of the antenna 18 may be increased, or decreased if sodesired, to substantially match or equal the range of integrated circuit36 input impedance.

The design of the second antenna elements 22 assists in modifying thecurrent distribution at the second ends 28 of the first and secondconductors 24, 26 of the first antenna element 20. By modifying thecurrent distribution at the second ends 28 of the conductors 24, 26, thesecond antenna elements modify the imaginary component of the impedanceof the antenna 18 to balance the imaginary component of the inputimpedance of the integrated circuit 36. When the real impedance of theantenna 18 and the integrated circuit 36 are substantially matched andthe imaginary impedance components of the antenna 18 and integratedcircuit 36 are balanced, the radio frequency energy absorbed by theantenna is efficiently transferred from the antenna 18 into theintegrated circuit 36.

At the second end 28 of each conductor 24, 26, a second antenna element22 is electrically connected to the second end 28 of the conductors 24,26. To help balance the capacitive reactance of the integrated circuit36, the first portion 32 and second portion 34 of the second antennaelements 22 are selected to introduce a primarily inductive reactanceinto the antenna 18 impedance and an associated phase shift in the radiofrequency signal. The second antenna elements 22 may also have someminor portion of associated capacitive reactance, but the net inductiveimpedance of the second antenna elements 22 assists in balancing thecapacitive impedance of the integrated circuit. The portions 32, 34 ofthe second antenna elements 22 may be in the form of closed loops withcircumference ranging from as small as ⅛ the wavelength of the radiofrequency signal to as large as ½ the wavelength of the radio frequencysignal. The magnitude of the effect of the second antenna element 22impedance is determined by the distribution of electrical currents alongthe length of the first portion 20 of the antenna 18 and at the secondend 28 of each conductor 24, 26. The presence of the second antennaelement 22 assists in modifying the boundary conditions for theelectrical currents, compared to the current distribution in dipoleantennas known in the prior art. The modified boundary conditionsintroduce an additional phase shift in the current distribution in theantenna, compared to the phase shifts of dipole antennas known in theprior art. The phase shifts in the electrical current distributionintroduced by second antenna element 22 have the effect of modifying thereflection of radio frequency energy at the second ends 28 of the firstantenna element 20, compared to the dipole antenna known in the priorart. By selecting the second antenna elements 22 based on the teachingsof this specification, the imaginary component of the antenna 18impedance can be selected to be inductive, thereby balancing the(capacitive) imaginary component of the integrated circuit 36.

The design of the antenna 18 assists in matching the real part of theantenna impedance, Re Z_(ANT), to the real component of the integratedcircuit input impedance, Re Z_(IC) to assist in efficiently coupling theradio frequency signal from the antenna 18 to the integrated circuit 36.The imaginary part of the antenna 18 impedance, Im Z_(ANT), balances theimaginary part of the integrated circuit 36 input impedance, Im Z_(IC),but is preferably opposite in phase. Under these conditions of matchedand balanced impedance components, the radio frequency power absorbed bythe antenna 18 couples efficiently to the integrated circuit.

On embodiment of preferable operating conditions of the RFID tag 10 aresummarized a follows:Re Z_(IC)˜Re Z_(ANT)and|Im Z_(IC)|˜|Im Z_(ANT)|, withφ(Z_(IC))˜−φ(Z_(ANT)),where φ is the phase angle of the complex impedance.

Even if it is not possible to exactly match the antenna 18 compleximpedance to the integrated circuit input complex impedance at the RFIDoperating frequency, a substantially or approximately close impedancematch at the operating frequency will result in more efficient couplingof the antenna 18 to the integrated circuit 36, compared to a poormatch.

FIG. 2 is a graph illustrating the calculated impedance of a prior artfolded dipole antenna having a diopole length (distance a of 140 mm anda end length (distance b) of 10 mm. The line 50 plots the real componentRe Z_(ANT) of the antenna impedance as a function of frequency. The line52 plots the imaginary component, Im Z_(ANT), of the antenna impedanceas a function of frequency. Note the values for Re Z_(ANT) and ImZ_(ANT) given for a radio frequency range of 915 MHz; at 915 MHz,Z_(PRIOR ART DIPOLE ANT)=(24.6 Ω, −j 13.6 Ω).

FIG. 2 shows the calculated values of the real and imaginary componentsof the complex impedance of a prior art folded loop dipole antenna. Thecalculations were performed using an antenna modeling program (NEC:Numerical Electromagnetics Code, available commercially as NEC WINProfrom Nittany Scientific, Inc.). Note that the complex impedance at 915MHz is approximately (24.575 Ω−j13.93 Ω). Near the radio frequency ofinterest (915 MHz), the prior art folded dipole antenna shows a smallreal impedance (resistive) component and a small imaginary impedancecomponent with negative (i.e., capacitive) phase. The small magnitude ofthe real (24 Ω resistive) component of the folded dipole impedance doesnot match the larger real (65 Ω resistive) component of the integratedcircuit input impedance. The small magnitude (13.93 Ω capacitive) of theimaginary component of the folded dipole impedance does not match thelarger magnitude (720 Ω capacitive) of the imaginary component of theintegrate circuit input impedance. The phase (−j, capacitive) of theimaginary component of the folded dipole impedance is the same as thephase of the phase (−j, capacitive) of the imaginary component of theintegrated circuit input impedance. Therefore, the imaginary componentof the folded dipole antenna is not balance the imaginary component ofthe integrated circuit input impedance so as to substantially offset(cancel) one against the other. Under these conditions of mismatchedreal components and unbalanced imaginary components of the antenna andintegrated circuit impedances, the electromagnetic signal absorbed bythe antenna will couple to the integrated circuit with low efficiencyi.e. low power transfer.

FIG. 3 is a graph illustrating the calculated impedance of the antenna18 of the RFID tag of the present invention, where distance a equaled140 mm and distance b equaled 10 mm. Note that the scale of this graphis different from the scale of the graph in FIG. 2, so that the largerimpedance values characteristic of the antenna design of the presentinvention can be more clearly displayed. The line 54 plots the realcomponent Re Z_(ANT) of the antenna 18 impedance as a function offrequency. The line 56 plots the imaginary component, Im Z_(ANT), of theantenna 18 impedance as a function of frequency. Note the values for ReZ_(ANT) and Im Z_(ANT) given for a frequency of 915 MHz:;Z_(PRESENT INVENTION DIPOLE ANT)=(67.0 Ω+j 751.5 Ω). The calculationswere performed using the antenna modeling program mentioned above (NEC:Numerical Electromagnetics Code.) Near the radio frequency of interest(915 MHz), the antenna 18 shows a real (resistive) impedance componentand an imaginary impedance component with positive (i.e., inductive)phase. The magnitude of the real (67 Ω resistive) component of theimpedance of the inventive antenna of this example approximately matchesthe real (65 Ω resistive) component of the integrated circuit 36 inputimpedance. The magnitude (751 Ω inductive) of the imaginary component ofthe impedance at the inventive antenna of this example approximatelymatches the magnitude (720 Ω capacitive) of the imaginary component ofthe integrated circuit 36 input impedance. The phase (+j, inductive) ofthe imaginary component of the impedance of the inventive antenna ofthis example is opposite to the phase (−j, capacitive) of the imaginarycomponent of the integrated circuit 36 input impedance. The imaginarycomponent of the impedance/inventive antenna of this example and theintegrated circuit 36 input impedance approximately balance, so as tosubstantially offset (or cancel) each other. In this preferred mode ofmatched real components and balanced imaginary components of the antenna18 and integrated circuit 36 impedances, the electromagnetic signalabsorbed by the antenna 18 will antenna couple to the integrated circuit36 with high efficiency, as compared to the prior folded dipole antennadiscussed above related to FIG. 2.

The dielectric substrate 12 may be any dielectric material known in theart. Examples of suitable dielectric materials for substrate 12 includepolyethylene terephthalate (commonly known as polyester or PET),polyethylene naphthanate (commonly known as PEN), copolymers of PET andPEN, polyimide, and polypropylene. Preferably, the thickness of thedielectric substrate 12 is in the range of 0.010 mm to 0.200 mm, andmore preferably, within the range of 0.025 mm to 0.100 mm. However, thedielectric substrate may be any thickness and may even be a non-uniformthickness.

An example of a suitable integrated circuit 36 is commercially availablefrom Philips Semiconductors, based in Eindhoven, Netherlands, under thepart number SL3ICS30.

The antenna 18 may be made of any type of conductive material, such awire, a conductive metal pattern (such as those formed from metal foilssuch as etched aluminum, etched copper, plated copper and the like), aprinted conductive pattern (such as those made from conductive inks, orother metal-containing materials, optionally including process steps toimprove conductivity), a pressed copper powder (for example as disclosedin published U.S. Patent Application 2003/0091789, which is herebyincorporated by reference), printed or pressed graphite or carbon black,or other conductive materials known to those skilled in the art.

The antenna 18 shown in FIG. 1 is a dipole antenna with a firstconductor 24 and a second conductor 26. However, other well-knownantennas known in the art may be used in combination with the secondantenna element 22, for example, a folded dipole, a spiral antenna, a“z-shaped” antenna, a loop antenna or their complements, such as slotantennas.

The operation of the present invention will be further described withregard to the following detailed examples. These examples are offered tofurther illustrate the various specific and preferred embodiments andtechniques. It should be understood, however, that many variations andmodifications may be made while remaining within the scope of thepresent invention.

EXAMPLES

One preferred embodiment of the RFID tag 10 of the present invention wasmade, as illustrated in FIG. 1. The dimensions of the antenna 18 areillustrated in FIG. 1, and the antenna of this example included an “a”distance of 140 mm and a “b” distance of 10 mm. A comparative example ofa prior art folded dipole antenna was also made.

The antenna 18 was made by plating 0.118 mm thickness copper on a 0.025mm thick polyimide substrate 12 commercially available from DupontElectronics, based in Wilmington, Del., under the trade name Kapton Efilm. Photoresist material commercially available from MacDermid, Inc,based in Wilmington, Del. under trade name MacDermid SF 320 waslaminated to the surface of the plated copper film. The photoresistmaterial was applied to the substrate, in the form of the desired finalantenna 18.

The exposed copper was etched away, leaving copper in the pattern of thedesired final antenna 18. The remaining photoresist material wasstripped off the copper, using the methods suggested by the photoresistmanufacturer. After stripping the photoresist material, the patternedcopper antenna 19 in its final form was left on the polyimide substrate12. The resultant 0.018 mm copper traces were of the same thickness asthe starting copper foil thickness. The copper traces were 1.000 mmwide, except for the two short traces connected to the integratedcircuit connection pads; these two traces were 0.100 mm wide. Theintegrated circuit was connected to the ends 27.

The antenna 20 had an ‘a’ dimension of 140 mm with a ‘b’ dimension of 10mm. The first portion of the second antenna element was formed as acircle with a radius of 5 mm and attached to end 28 of the firstconductor 24, with a ‘c’ dimension of 4 mm. The second portion of thesecond antenna element was formed as a circle with a radius of 5 mmattached to the end 28 of the second conductor 26, with a ‘d’ dimensionof 58 mm.

An integrated circuit 36 commercially available from PhilipsSemiconductors, based in Eindhoven, Netherlands, under the part numberSL3ICS30 was attached to the polyimide substrate 12 by anisotropicconductive film adhesive. This integrated circuit 36 had known inputimpedance characteristics of Z_(IC)=(65 Ω−j 720 Ω) at 915 MHz.

The comparative example antenna was formed using the same procedures andof the same dimensions as the inventive antenna described above exceptthe comparative antenna had no second antenna elements and the ends 28joined.

Since means of measuring the real and imaginary antenna impedanceprovides questionable results because the measuring means loads theantenna, thus affecting the measured values, a preferred means toevaluate balance between the complex impedance of the antenna and the ICis to measure read distance. A greater read distance is indicative ofcloser balanced impedances.

The read distance of the inventive UHF RFID tag 10 was measured with a915 MHz RFID reader, commercially available from SAMSys Technologies,Richmond Hill, Ontario, Canada, under the trade name SAMSYS, part numberMP9320, operated at 1 watt output power. The RFID reader was connectedto a circular polarized antenna, commercially available from CushcraftCorporation, Manchester, N.H., under the trade name CUSHCRAFT, partnumber S9028PC.

The read distance of the comparison example of the simple dipoleantenna, with same model Philips integrated circuit model SL3ICS30 wasless than 0.3 m. The read distance of the example inventive UHF RFID tag10 was 1.5 m. TABLE 1 Real and Imaginary Components of Impedance of theIntegrated Circuit, Comparative Example, and Example of the PresentInvention Impedance (Z) Frequency Re Z Im Z MHz Ohms (Ω) Ohms (Ω)Integrated Circuit 915 65.0 −j 720   Comparative Example 915 24.6 −j13.9  (Prior Art Folded Dipole) Example 1 900 31.9 +j 513.0 915 67.0 +j751.4

The tests and test results described above are intended solely to beillustrative, rather than predictive, and variations in the testingprocedure can be expected to yield different results.

The present invention has now been described with reference to severalembodiments thereof. The foregoing detailed description and exampleshave been given for clarity of understanding only. No unnecessarylimitations are to be understood therefrom. All patents and patentapplications cited herein are hereby incorporated by reference. It willbe apparent to those skilled in the art that many changes can be made inthe embodiments described without departing from the scope of theinvention. Thus, the scope of the present invention should not belimited to the exact details and structures described herein, but ratherby the structures described by the language of the claims, and theequivalents of those structures.

1. An ultra high frequency (“UHF”) radio frequency identification(“RFID”) tag, comprising: a) a dielectric substrate; b) an antennaattached to the dielectric substrate, wherein the antenna comprises: i)a first antenna element, wherein the first antenna element comprises afirst conductor and a second conductor, wherein each conductor has afirst end and a second end opposite the first end, wherein the firstantenna element is selected to provide a desired operating frequencyrange of the antenna; and ii) a second antenna element, wherein thesecond antenna element comprises a first portion and a second portion,wherein the first portion is attached to the second end of the firstconductor and the second portion is attached to the second end of thesecond conductor, and wherein the second antenna element is selected toprovide a desired impedance value of the antenna; and c) an integratedcircuit attached to the first end of the first conductor and the firstend of the second conductor.
 2. The UHF RFID tag of claim 1, wherein theintegrated circuit has a first impedance value, and wherein the antennahas a second impedance value, and wherein the magnitude of the realcomponent of the second impedance value is substantially similar to themagnitude of the real component of the first impedance value, and themagnitude of the imaginary component of the second impedance value issubstantially similar to the magnitude of the imaginary component of thefirst impedance value, and wherein the phase of the imaginary componentof the first impedance value and the phase of the imaginary component ofthe second impedance value are opposite.
 3. The UHF RFID tag of claim 2,wherein the first impedance value has a first real component value and afirst imaginary component value, wherein the second impedance value hasa second real component value and a second imaginary component value,wherein the first real component value is equal to the second realcomponent value and wherein the magnitude of the imaginary component ofthe second impedance value is equal to the magnitude of the imaginarycomponent of the imaginary component of the first impedance value, andwherein the phase of the imaginary component or the first impedancevalue and the phase of the imaginary component of the second impedancevalue are opposite.
 4. The UHF RFID tag of claim 2, wherein the firstportion of the antenna has a first real component value and a firstimaginary component value and the second portion of the antenna has asecond real component value and a second imaginary component value, andwherein the second portion of the antenna is selected to provide asecond real component value and second imaginary component value whichassist in balancing the first real component value and the firstimaginary component value to provide the second impedance value of theantenna substantially similar to the first impedance value of theintegrated circuit.
 5. The UHF RFID tag of claim 4, wherein the firstportion of the antenna has a first real component value and a firstimaginary component value and the second portion of the antenna has asecond real component value and a second imaginary component value, andwherein the second portion of the antenna is selected to provide asecond real component value and second imaginary component value whichassist in balancing the first real component value and the firstimaginary component value to provide the second impedance value of theantenna equal to the first impedance value of the integrated circuit. 6.The UHF RFID tag of claim 1, wherein the first portion of the secondantenna element and the second portion of the second antenna element arein the shape of closed loops.
 7. The UHF RFID tag of claim 1, whereinthe first portion of the second antenna element and the second portionof the second antenna element are in the shape of polygons.
 8. The UHFRFID tag of claim 1, wherein the first portion of the second antennaelement is dissimilar in shape to the second portion of the secondantenna element.
 9. The UHF RFID tag of claim 1, wherein the firstportion of the second antenna element is similar in shape to the secondportion of the second antenna element.
 10. The UHF RFID tag of claim 1,wherein the first portion of the second antenna element is different insize than the second portion of the second antenna element.
 11. The UHFRFID tag of claim 1, wherein the first conductor and second conductorinclude meanders.
 12. The UHF RFID tag of claim 1, wherein the firstconductor and second conductor are made from a wire, patternedconductive foils, or printed conductive traces.
 13. The UHF RFID tag ofclaim 1, wherein the first antenna element is made from a differentconductive material than the second antenna element.
 14. The UHF RFIDtag of claim 1, wherein the dielectric substrate includes a dielectricconstant ε≦10*ε₀ between 850 MHz and 960 MHz, wherein ε₀ is thepermittivity of free space (ε₀=8.85×10⁻¹² C²/N.m²).
 15. The UHF RFID tagof claim 1, wherein the dielectric substrate includes a first side and asecond side opposite the first side, wherein the antenna is attached tothe first side and the integrated chip is attached to the second side.16. The UHF RFID tag of claim 1, wherein the distance between the firstportion of the second antenna element and the first conductor isdifferent from the distance between the second portion of the secondantenna element and the second conductor.
 17. The UHF RFID tag of claim1, wherein the length of the first conductor is different than thelength of the second conductor.
 18. A method of manufacturing an ultrahigh frequency (“UHF”) radio frequency identification (“RFID”) tag,comprising the steps of: a) providing a dielectric substrate; b)selecting an antenna comprised of a first antenna element and a secondantenna element, wherein the first antenna element is selected toprovide a desired operating frequency range of the antenna, wherein thesecond antenna element is selected to provide a desired impedance value,wherein the first antenna element comprises a first conductor and asecond conductor, wherein each conductor has a first end and a secondend opposite the first end, and wherein the second antenna elementcomprises a first portion and a second portion; and c) attaching theantenna to the dielectric substrate such that the first portion of thesecond antenna element is attached to the second end of the firstconductor and the second portion of the second antenna element isattached to the second end of the second conductor; and d) attaching anintegrated circuit to the first end of the first conductor and the firstend of the second conductor.
 19. The method of claim 18, wherein theintegrated circuit has a first impedance value, and wherein the antennahas a second impedance value, and wherein the magnitude of the realcomponent of the second impedance value is substantially similar to themagnitude of the real component of the first impedance value, and themagnitude of the imaginary component of the second impedance value issubstantially similar to the magnitude of the imaginary component of thefirst impedance value, and wherein the phase of the imaginary componentof the first impedance value and phase of the imaginary component of thesecond impedance value are opposite.
 20. The method of claim 19, whereinthe first impedance value has a first real component value and a firstimaginary component value, wherein the second impedance value has asecond real component value and a second imaginary component value,wherein the first real component value is equal to the second realcomponent value and wherein the magnitude of the imaginary component ofthe second impedance value is equal to the magnitude of the imaginarycomponent the first impedance value, and wherein the phase of theimaginary component of the first impedance value and the phase of theimaginary component of the second impedance value are opposite.
 21. Themethod of claim 19, wherein the first portion of the antenna has a firstreal component value and a first imaginary component value and thesecond portion of the antenna has a second real component value and asecond imaginary component value, and wherein the second portion of theantenna is selected to provide a second real component value and secondimaginary component value which assist in balancing the first realcomponent value and the first imaginary component value to provide thesecond impedance value of the antenna substantially similar to the firstimpedance value of the integrated circuit.
 22. The method of claim 21,wherein first portion of the antenna has a first real component valueand a first imaginary component value and the second portion of theantenna has a second real component value and a second imaginarycomponent value, and wherein the second portion of the antenna isselected to provide a second real component value and second imaginarycomponent value which assist in balancing the first real component valueand the first imaginary component value to provide the second impedancevalue of the antenna equal to the first impedance value of theintegrated circuit.
 23. The method of claim 18, wherein the firstportion of the second antenna element and the second portion of thesecond antenna element are in the shape of closed loops.
 24. The methodof claim 18, wherein the first portion of the second antenna element andthe second portion of the second antenna element are in the shape ofpolygons.
 25. The method of claim 18, wherein the first portion of thesecond antenna element is dissimilar in shape to the second portion ofthe second antenna element.
 26. The method of claim 18, wherein thefirst portion of the second antenna element is similar in shape to thesecond portion of the second antenna element.
 27. The method of claim18, wherein the first portion of the second antenna element is differentin size than the second portion of the second antenna element.